High tensile strength joint for connecting rods and fittings

ABSTRACT

A joint exhibits high tensile strength. The joint includes a solid rod having a slit or opening into which a wedge is inserted. The rod and wedge are inserted into a fitting. The internal surface of the fitting has a contour which continuously and nonlinearly varies with distance along the fitting. The wedge has a dimension having a similar contour. The shape of the contour can be described by a polynomial of order two or higher. The joint can be used to construct a sucker rod for an oil well, or it can be used in other applications. The joint can support high tensile loads, over long distances, while occupying a very narrow tubing bore.

BACKGROUND OF THE INVENTION

The present invention comprises a joint which connects a rod and a fitting, wherein the rod and fitting are subjected to high-tension loads. The invention is especially useful in constructing a sucker rod for oil wells. The invention may be used, however, in many other applications, such as in pre-stressed concrete, and in tension members for bridges.

A sucker rod is a long rod formed of a plurality of sections, capable of connecting a pump, located at the bottom of an oil well, with a lifting device, or pump jack, located at the surface. Each section may include a rod portion and a fitting portion, each rod being inserted into a fitting. In practice, a sucker rod comprises a long chain of rods and fittings and couplings. Because some wells may be deeper than 16,000 feet, the sucker rod must have very high tensile strength, so that the rod does not break under its own weight plus that of the fluid, as it is pulled up by the pump jack, and pulled down by gravity. The problem of designing a sucker rod having the necessary tensile strength is made more difficult by the fact that the rod typically must fit within a tubing of relatively small diameter.

Various sucker rods have been proposed in the prior art, as exemplified by U.S. Pat. Nos. 4,205,926, 4,430,018, and 6,193,431. The disclosures of these patents are hereby incorporated by reference.

While the above-cited patents provide useful solutions, the patented devices have disadvantages. Among other things, some of the prior art uses rods that are made of stranded wire. A stranded rod, by definition, has less than optimal tensile strength, because the strands do not occupy the entire cross-sectional area of the rod, and the filaments are not aligned exactly parallel to the rod axis.

In general, the prior art has not developed a sucker rod having sufficient tensile strength, while occupying a minimal cross-sectional area. There is still a need for a sucker rod which is stronger than sucker rods of the prior art, which incorporates advanced materials that are lighter than metal, and which still fits within a narrow tubing bore.

The present invention provides a joint which exhibits very high tensile strength, while minimizing the cross-sectional area required. The joint of the present invention can therefore be used to construct longer, lighter sucker rods which can still lift a useful payload of fluid. It can also be used in many other applications requiring the assembly of rods capable of carrying large tensile loads. However, the joint of the present invention is not intended to bear significant compression loads.

SUMMARY OF THE INVENTION

The present invention comprises a joint which includes a solid rod inserted into a fitting. The rod is preferably a carbon or graphite composite, and the fitting is preferably made of steel. The rod has an opening or slit at its ends, into which a wedge is inserted. The internal diameter of the fitting varies smoothly and nonlinearly with distance along the fitting. At the narrow end of the wedge, i.e. the end of the slit where the wedge terminates, the internal contour of the fitting becomes parallel to the axis of the rod. The wedge has a dimension which also varies smoothly and nonlinearly with distance. Preferably, the variation of the dimension of the wedge is substantially the same as that of the internal diameter of the fitting. That is, the contour of the fitting is substantially the same as the contour of a portion of the wedge. In a preferred embodiment, this contour can be described by a polynomial function having an order of at least two, such that the contour becomes parallel to the axis of the rod at the narrow end of the wedge where it terminates.

In a preferred embodiment, the wedge has a cruciform shape. In a more general case, the preferred wedge includes at least two mutually non-parallel vanes. However, the wedge could instead have only a single vane.

In assembling the joint, the wedge is prepared by forming at least one slit in the rod, so that the rod can accommodate the wedge. The wedge is then inserted into the rod, causing the rod to expand or swage outward. When the rod, with the wedge inserted, is inserted into the fitting, the joint occupies virtually all the space within the fitting, at all points where the rod and wedge are present.

The joint of the present invention exhibits very high strength under tension.

The joint may also include a plug which is inserted into the fitting which prevents the rod from being dislodged with respect to the fitting in the presence of relatively small compressive loads.

The joint is particularly suited for use in constructing sucker rods for oil wells, because the joint can accommodate very high tensile loads, while occupying a long and narrow tubing bore. The joint can also be used in applications other than in oil production.

The invention therefore has the primary object of providing a joint which exhibits high tensile strength.

The invention has the further object of providing a joint which can be used to construct a long rod, wherein the rod has high tensile strength while fitting within a tubing bore of relatively small diameter.

The invention has the further object of providing a joint for use in a sucker rod for an oil well.

The invention has the further object of providing a joint which uses a solid rod, and which thereby takes full advantage of the available cross-section of the rod, providing a structure of high tensile strength.

The reader skilled in the art will recognize other objects and advantages of the present invention, from a reading of the following brief description of the drawings, the detailed description of the invention, and the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 provides a perspective view of the joint of the present invention, showing a rod inserted into a fitting.

FIG. 2 provides a cross-sectional view of the joint of the present invention, taken along the line II-II of FIG. 1.

FIG. 3 provides a side view of a swaged rod, with the fitting removed, used in the present invention, the rod having a cruciform wedge inserted therein.

FIG. 3 a provides a side view of the rod used in the present invention, showing an opening or slit formed therein, before a wedge has been inserted.

FIG. 4 provides an end view of the rod and the cruciform wedge of FIG. 3.

FIG. 4 a provides an end view of the slitted rod of FIG. 3 a.

FIG. 5 provides a perspective view of the cruciform wedge used in the present invention.

FIG. 6 provides a side view of a swaged rod, with the fitting removed, used in the present invention, the rod having a multiply-vaned wedge inserted therein.

FIG. 7 provides an end view of the rod and the multiply-vaned wedge of FIG. 6.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 provides a perspective view showing the joint of the present invention. The joint includes rod 1 inserted into fitting 2.

In the preferred embodiment, the rod is formed of a composite including graphite, or other carbon, and an organic resin. The graphite exists in the form of tightly-packed fibers or filaments, which maintain their identities as having individual, small diameters. The organic resin is similar to an adhesive, and binds the fibers effectively into a single, solid rod.

In the preferred embodiment, the fitting is a single piece of machined metal, preferably formed of high-strength steel. The steel forming the fitting preferably has a yield strength in the range of 110 ksi-140 ksi. The material must not be too brittle, and must allow reasonable elongation (of the order of greater than about 15%) before failure. The steel may be selected according to its corrosion resistance properties, if desired.

Although the invention will be described in terms of a graphite composite rod inserted into a steel fitting, it should be understood that the invention should not be deemed limited to particular materials. It is possible that the rod could be some other material, even metal. It is also possible that the fitting could be constructed of something other than steel, if such material has sufficient strength.

FIG. 2 provides a cross-sectional view of the joint of the present invention, taken along the line II-II of FIG. 1. The line II-II is somewhat off-center, as will be apparent later in this description.

FIG. 2 shows solid rod 1 inserted within fitting 2. The rod includes a slit which accommodates a wedge 3. The wedge is inserted within the slit, and occupies substantially all of the space defined by the slit. The wedge therefore causes the rod to be swaged outward. An adhesive 5, indicated symbolically by dashed lines in FIG. 2, is provided between the outer surface of the rod and the inner surface of the fitting.

A plug 4 is screwed into the fitting, with the aid of threads 6. The plug provides resistance to small, incidental compressive forces. That is, if the assembly of rods and fittings is momentarily compressed, the plug prevents the rod from becoming dislodged and pushing into the open, larger diameter end of the fitting. The plug is preferably made of metal.

It is an important aspect of the present invention that the wedge be smoothly curved, and that the inside surface of the fitting be smoothly curved. Also, the curvature of the wedge has substantially the same shape as the curvature of the interior surface of the fitting.

More precisely, the internal diameter of the fitting varies smoothly and nonlinearly with distance along the fitting. And the wedge has a dimension which similarly varies smoothly and nonlinearly with distance along the wedge.

Thus, as shown in FIG. 2, the fitting has a threaded region, at and to the right of the plug 4, and a contoured region, to the left of the plug, in which the inside surface of the fitting is contoured as described above.

In one preferred embodiment, the variation of the internal diameter of the fitting (as well as the thickness and the width of the wedge) is a cubic spline, defined as follows:

D=D _(throat)+2×R _(delta)×[1−1.5(L−z)/L+(L−z)³/2L ³]  (1)

where D is the internal diameter of the fitting;

-   -   D_(throat) is the diameter of the rod plus a clearance         (typically about 0.01 inches);     -   L is the length of the contoured internal diameter;     -   R_(delta) is (D_(max)−D_(throat))/2;     -   D_(max) is the desired maximum internal diameter of the fitting         at the point where the width of the wedge is at its maximum; and     -   z is the distance from the start of the contoured shape of the         internal diameter.

Thus, R_(delta) is the increase in the internal radius of the fitting caused by the swaging effect of the wedge.

The above equation shows that at the start of the wedge, where z=0, the diameter is D=D_(throat). At the right-hand edge of the wedge, where z=L, the diameter is D=D_(throat)+2R_(delta)=D_(max).

Note also that the slope of the above-defined contour is zero at z=0. That is, the slope of the contour is calculated as the first derivative of D (equation (1)), as a function of z, and evaluated for z=0. This is another way of saying that the slope of the contour equals the slope of the rod, at the narrow (unswaged) end of the rod, and both such slopes are zero.

The thickness of the wedge, as a function of y, which is defined by FIG. 5, is given in the following Equation (2). In Equation (2), the axes are different from those implied in Equation (1).

T ₁(y)=t ₀+(t _(max) −t ₀)[1−1.5(L _(wedge) −y)/L _(wedge)+(L _(wedge) −y)³/2L _(wedge) ³]  (2)

where:

t₀=thickness of wedge at the thin end=t_(kerf)−2t_(bondline)

t_(kerf)=nominal thickness of the kerf (as illustrated in FIG. 3 a)

t_(bondline)=nominal thickness of the bondline (about 0.005 inches)

t_(max)=maximum thickness of the wedge=0.9(D_(max)−D_(throat))−4t_(bondline)

L_(wedge)=0.99(L) (99% of the length of the cut, L_(cut)) (see FIG. 3 a)

D_(max) is the same as defined for Equation (1)

D_(throat) is the same as defined for Equation (1)

y=distance from the thin end of the wedge piece.

Note that Equation (2) is the same for T₂(y), which is the thickness of the other vane of the wedge, as shown in FIG. 5.

The width of the wedge, as defined in FIG. 5, is given by Equation (3), as follows:

W ₁(y)=W ₀+(W _(max) −W ₀)[1−1.5(L _(wedge) −y)/L _(wedge)+(L _(wedge) −y)³/2L _(wedge) ³]  (3)

where:

-   -   W₀=width of wedge at the narrow end (about         0.98(D_(throat)))−2t_(bondline))     -   W_(max)=maximum width of wedge at wide end (about         0.95(D_(max))−2t_(bondline))     -   t_(bondline)=nominal thickness of the bondline (about 0.005         inches)     -   L_(wedge)=0.99(L) (99% of length of the cut, L_(cut)) (see FIG.         3 a)     -   D_(max)=the desired maximum diameter at the maximum width of the         wedge     -   D_(throat)=the diameter of the rod plus a clearance (typical         clearance being about 0.01 inches)     -   y=distance from the thin end of the wedge piece

Similarly to Equation (2), Equation (3) is the same for W₂(y), which is the thickness of the other, relatively perpendicular vane of the wedge, shown in FIG. 5.

Thus, at the right-hand edge of the wedge (y=L_(wedge)), the wedge thickness is t_(max), and the wedge width is W_(max).

At the left-hand edge of the wedge (y=0), Equation (2) yields a value of t₀ for the wedge thickness, and Equation (3) yields a value of W₀ for the wedge width. Thus, Equations (2) and (3) account for the fact that the wedge thickness, in practice, has a small non-zero value at its thin edge.

At the point where the thickness of the wedge becomes less than a certain small value, the wedge can be trimmed, so that the measured thickness becomes the starting thickness of the wedge.

In the equations shown above, it is seen that the internal diameter of the fitting, and the thickness of the wedge, and the width of the wedge, all vary according to a third-order polynomial function of distance along the axis of the joint.

The above equations represent only one of many possible embodiments. In the general case, the internal diameter of the fitting, and the thickness and width of the wedge, must vary smoothly and nonlinearly with distance. Also, the contour or shape of the inside of the fitting should be the same as the contour of the thickness of the wedge, which should be the same as the variation of the width of the wedge.

The desired maximum inner bore diameter of the fitting corresponding to the end of the wedge (the right-hand side of the wedge in FIG. 2) is selected according to the following criteria:

1) the cross-sectional area of the fitting is at least twice the cross-sectional area of the rod at any point along the fitting which is occupied by the wedge; and

2) the maximum diameter is greater than about 1.3 times the diameter of the rod and less than about 1.5 times the diameter of the rod.

Also, in practice, the maximum width of the wedge is not quite equal to the full diameter of the fitting.

The wedge should be relatively short and compact. The length of the wedge is preferably less than five times the diameter of the rod, allowing for a shorter fitting that is less than 5.3 times the diameter of the rod.

In general, substantially all of the space within the fitting, at all points where the rod and wedge are present, is occupied by the components of the invention, namely the wedge, the rod, and to a minimal extent, the adhesive. There is virtually no “air” or unoccupied space within the fitting, where the rod is present.

The wedge preferably has a cruciform shape. FIGS. 3-5 illustrate this feature. The cruciform wedge is illustrated in the perspective view of FIG. 5, which shows vertical vane 50 and horizontal vane 51. The vanes can be machined as a unitary part, or they could be separately constructed and suitably joined. Both vanes have a thickness which increases from left to right, as shown in the drawing. The variation in thickness of each vane could be as given in Equation (2), discussed above. If Equation (2) is used to define the variation of the thickness of one of the vanes, it should be used for both vanes. In general, all vanes should have the same variation of thickness with distance along the wedge.

FIG. 3 shows the wedge 52 inserted within the rod 53. The end view of FIG. 4 further illustrates the cruciform structure of the wedge, when it is embedded in the rod 53.

FIG. 3 a shows the rod 53 having an opening or slit 55 formed therein. FIG. 3 a represents the state of the rod before a wedge has been inserted. The figure also indicates the definition of the quantity t_(kerf), which is the thickness of the kerf, which is the material removed from the rod in forming the slit. FIG. 4 a shows the corresponding end view of the rod of FIG. 3 a.

The wedge could have greater numbers of vanes. FIGS. 6 and 7 illustrate an example in which the wedge comprises three vanes. The side view of FIG. 6 shows two vanes 61, 62, and the end view shows all three vanes 61, 62, and 63.

In the preferred embodiment, the wedge has at least two vanes.

It is also possible for the wedge to have only one vane. In this case, the swaging effect would occur in only one direction. This arrangement would result in a weaker rod assembly, but might be useful in certain applications.

In the above-described example, the internal diameter of the fitting, and the outer diameter of the rod, and the thickness of the wedge, vary according to the cube of the distance along the fitting. This curvature need not be exactly as shown in the example. Rather, it is a feature of the invention that the curvature be described by a polynomial equation having an order of at least two. Such equation may represent the deflected shape of a cantilever beam under an end load. Thus, the diameter of the fitting could vary with the square or the cube, or some higher power, of the distance.

It is important that the above-described curvature be smooth and continuous, and that the curvature continue along substantially all of the distance along which the rod is inserted into the fitting. If instead the interior diameter of the fitting varied linearly with distance (i.e. defining a conic shape), stress concentrations would form at kinks in the fitting, causing weakening and eventual failure of the joint. The curvature may be consistent with the deflected shape of a beam under distributed loads.

In making the joint of the present invention, a plurality of slits is formed in the rod, an adhesive is inserted in the slits, and the wedges are inserted into the slits. The length of each slit should correspond to the length of the wedge to be inserted. In forming the slits, some of the material of the rod is removed, this material being known as “kerf”. When the wedges are fully inserted, substantially all of the space within the rod is filled. More particularly, the wedges, when inserted, substantially conform to the contour of the adjacent material of the rod, to insure that virtually all of the space is filled. The slits are very small relative to the diameter of the rod, and are not sufficient to cause the rod to split, or otherwise to significantly weaken the rod.

The adhesive between the wedge and the rod prevents the wedge from being forced out. It is possible to avoid the use of an adhesive for this purpose if one has enough friction between surfaces to hold the wedge in place.

In the preferred embodiment, the rod is a pultruded solid composite, and is compatible with high-temperature epoxy resins. The choice of a solid composite rod makes it feasible to use high-strength carbon or graphite fibers. Since the carbon or graphite fibers fill substantially all of the cross-sectional area of the rod (until the wedge has been inserted), the present invention takes advantage of the full cross-section, and results in a stronger rod, for a given cross-sectional area. That is, the joint can accommodate loads of more than three times those of a conventional joint having the same size, such as the joint shown in U.S. Pat. No. 4,205,926.

The use of a solid rod contrasts with the use of stranded cables of the prior art. Cables inherently have spaces between strands, or between groups of strands, resulting in not all of the cross-sectional area being used in supporting a load.

The high strength of the rod makes it possible to design the joint such that the rod and fitting are of relatively small diameters. Thus, the rod and fitting are more likely to be successfully operated within small diameter tubes, such as the bore of an oil well.

However, the invention is not limited to a rod or fitting of any particular diameter. What is important is that the rod initially be of solid construction, and that it initially have a constant diameter. The invention can be scaled such that larger and thicker rods and fittings could be used.

Although the rod has been described as graphite, or as a composite of graphite and resin, the rod may be made of another material, such as metal or fiberglass.

The threaded end of the fitting allows multiple segments to be connected using a standard coupling technique.

The joint of the present invention is intended to transfer large loads in tension, but not compressive loads. The plug caps off the end of the rod, and will withstand relatively small, incidental compression loads that might otherwise cause the rod to unseat from the fitting.

The present invention is not limited to use with sucker rods in the oil industry. It could be used in structural applications such as tension rods for pre-stressing of concrete and other materials which are strong in compression. It could be used in making guy wires or cables. It could also be used for pre-stressed concrete structures and/or in making suspension supports, such as are used for bridges.

The invention can be modified in various ways. As indicated above, the number of vanes of the wedge can be varied. The materials used for the wedge, the rod, and the fitting can be changed, consistent with the requirements of stiffness. The exact contour of the relevant surfaces of the fitting and wedge can be varied, as long as the contour is smooth and nonlinear. These and other modifications, which will be apparent to the reader skilled in the art, should be considered within the spirit and scope of the following claims. 

What is claimed is:
 1. A joint, comprising: a) a fitting, b) a solid rod having an end which is inserted at least partly into the fitting, c) the rod having an opening formed in said end, and d) a wedge being inserted into the opening of the rod, wherein the fitting has an internal diameter which varies smoothly and nonlinearly with distance along the fitting, and wherein the wedge has a dimension which varies smoothly and nonlinearly with distance along the wedge.
 2. The joint of claim 1, wherein a variation of the dimension of the wedge with distance is substantially similar to a variation of the diameter of the fitting with distance.
 3. The joint of claim 2, wherein the diameter of the fitting, and the dimension of the wedge, vary with at least a second power of the distance along the fitting or wedge, respectively.
 4. The joint of claim 1, wherein the wedge is made of a material having high stiffness.
 5. The joint of claim 1, wherein the fitting has a cross-sectional area and the rod has a cross-sectional area, and wherein the cross-sectional area of the fitting is at least twice the cross-sectional area of the rod.
 6. The joint of claim 1, wherein the wedge has a cross-sectional shape which is cruciform.
 7. The joint of claim 1, wherein the wedge includes at least two vanes which are non-parallel to each other.
 8. The joint of claim 1, wherein the wedge has a length which is less than about five times a diameter of the rod.
 9. The joint of claim 1, wherein the rod is solid except at said opening.
 10. The joint of claim 9, wherein substantially all open space within the rod is occupied by the wedge.
 11. The joint of claim 10, wherein substantially all space within the fitting, at a given point along a length of the fitting, is occupied by the rod or the wedge.
 12. The joint of claim 1, further comprising a plug which is screwed into the fitting such that the plug is positioned adjacent the end of the rod.
 13. A joint, comprising: a generally solid rod which is inserted into a fitting, the rod having a slit, a wedge being inserted into the slit, wherein the fitting has an inside surface having a contour which various smoothly and nonlinearly with distance along the fitting, wherein the wedge has a dimension which has a curvature similar to said contour, wherein the wedge tightly engages the rod, and wherein the rod tightly engages the fitting, such that the rod and wedge together occupy substantially all space within the fitting, at points where the rod and wedge are present.
 14. The joint of claim 13, wherein the contour is described by a polynomial equation having an order of at least two.
 15. The joint of claim 14, wherein the wedge has a cruciform shape.
 16. The joint of claim 14, wherein the wedge includes at least two vanes.
 17. The joint of claim 14, wherein the fitting has a cross-sectional area and the rod has a cross-sectional area, and wherein the cross-sectional area of the fitting is at least twice the cross-sectional area of the rod.
 18. The joint of claim 17, wherein the wedge has a length which is less than about five times a diameter of the rod. 